Techniques of Scientific Computing for Energy and the Environment.

Intro -- TECHNIQUES OF SCIENTIFIC COMPUTING FOR ENERGY AND THE ENVIRONMENT -- TECHNIQUES OF SCIENTIFIC COMPUTING FOR ENERGY AND THE ENVIRONMENT -- CONTENTS -- PREFACE -- STABILITYANALYSISOFABNORMALMULTIPLICATIONOFPLANKTONCONSIDERINGFLOWVELOCITY -- Abstract -- 1.Introduction -- 2.BasicEquation -- 2.1.NonlinearShallowWaterEquation -- 2.2.EcologicalModel -- 3.StabilityProblem -- 3.1.Lyapunov'sStabilityTheory -- 3.2.Linearization -- 3.3.DiscretizationbyFEM -- 4.EigenvalueProblem -- 4.1.Arnoldi'sMethod -- 4.2.ApplicationforGeneralizedEigenvalueProblem -- 5.ParameterIdentification -- 5.1.PerformanceFunction -- 5.2.Algorithm -- 5.3.SensitivityMatrix -- 6.InitialDistributionofPlankton -- 6.1.ModalAnalysis -- 6.2.EigenvalueProblembyFEM -- 6.3.SuperpositionofSpectra -- 6.3.1.PerformanceFunction -- 6.3.2.MinimizationMethod -- 7.NumericalExample -- 7.1.VerificationofEcologicalModel -- 7.1.1.Case1 -- 7.1.2.Case2 -- 7.2.AnalysisinLakeKasumigaura -- 7.2.1.InitialDistribution -- 7.2.2.StabilityAnalysis -- 8.Conclusion -- References -- ACHIEVINGHIGH-PERFORMANCECOMPUTINGINGEOMECHANICSBYDEVELOPMENTOFPARALLELFINITEELEMENTPACKAGE -- Abstract -- 1.Introduction -- 2.FiniteElementMethodPackageHydro-Geo -- 3.NumericalProcedure -- 4.ParallelHydro-GeoForSharedMemorySupercomputers -- 5.DistributedCalculation -- 5.1.DistributedFEMPackage -- 5.2.ParallelNumericalAlgorithmforSolvingtheLinearEquationsforCon-solidationProblem -- 6.EngineeringProblems -- 6.1.EmbankmentRising -- 6.2.BeskoDam -- 6.3.TheSettlementsofWarsawUnderground -- Conclusions -- References -- LARGE-SCALEDATAVISUALIZATIONUSINGMULTI-LANGUAGEPROGRAMMINGAPPLIEDTOENVIRONMENTALPROBLEMS -- Abstract -- 1.Introduction -- 2.ProgrammableFilters -- 3.AccessingVTKObject'sData -- 3.1.CreatingandManipulatingVTKArrays -- 3.2.DataPassingLibrary -- 3.3.PassingDatafromVTKObjecttoFortranRoutine -- 4.ProgrammableFiltersinC++.

4.1.SimplePipelineExample -- 4.2.PipelinewithFilter -- 4.3.UserFunction -- 5.ProgrammableFiltersinTcl -- 5.1.SimplePipeExample -- 5.2.PipelinewithFilter -- 6.UsingDynamicallyLinkedFunctionasFilterMethodinTcl -- 6.1.AddingNewBuilt-inCommandtoTclInterpreter -- 6.2.TclInterfacetoVTKLibrary -- 6.3.AccessingC++ObjectfromTclScript -- 6.4.vtkProgrammableFilterwithC++UserFunction -- 7.Conclusions -- AExampleofAccessingObjectDatawithRoutinesfromdplLibrary -- BdplLibrary -- B1.GettingPointsCoordinates -- B2.SettingPointCoordinates -- B3.GettingIndicesofNodesofTriangularElements -- B4.SettingScalarPointsAttribute -- B5.GettingScalarPointsAttribute -- B6.CreatingvtkUnstructuredGridfromArraysData -- References -- AN ANALYSIS OF FLOW AROUND A PROPELLER USING FICTITIOUS DOMAIN FINITE ELEMENT METHOD -- Abstract -- 1. Introduction -- 2. Computational Scheme -- 2.1. Basic Equation -- 2.2. Finite Element Interpolation -- 2.3. Fictitious Domain Formulation -- 2.4. Movement of Propeller -- 3. Numerical Study 1 -- 3.1. Numerical Model -- 3.2. Finite Element Mesh -- 3.3. Numerical Result -- 4. Numerical Study 2 -- 4.1. Model for Wind Tunnel Experiment -- 4.2. Numerical Result -- 5. Conclusions -- Acknowledgements -- References -- NUMERICALSIMULATIONOFSUPERSONICCOMBUSTIONUSINGPARALLELCOMPUTING -- Abstract -- 1.Introduction -- 2.Algorithm -- 3.ParallelImplementation -- 4.TestCaseConfiguration -- 5.Results -- 6.Conclusion -- Acknowledgements -- References -- INDEX -- Blank Page.

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Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.